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9.1 Consider the sinusoidal voltage (t ) 170 cos (120t 60) V. a) What is the maximum amplitude of the voltage? b) What is the frequency in hertz? c) What is the frequency in radians per second? d) What is the phase angle in radians? e) What is the phase angle in degrees? f) What is the period in milliseconds? g) What is the first time after t = 0 that = 170 V? h) The sinusoidal function is shifted 125/18 ms to the right along the time axis. What is the expression for (t)? i) What is the minimum number of milliseconds that the function must be shifted to the right if the expression for (t) is 170 sin 12t V? j) What is the minimum number of milliseconds that the function must be shifted to the left if the expression for (t) is 170 cos 12t V? 9.12 The expressions for the steady-state voltage and current at the terminals of the circuit seen in Fig. P9.12 are g 300 cos(5000t 93) V, i g 6 sin(5000t 123) A a) What is the impedance seen by the source? b) By how many microseconds is the current out of phase with the voltage? 9.14 A 400 Hz sinusoidal voltage with a maximum amplitude of 100 V at t = 0 is applied across the terminals of an inductor. The maximum amplitude of the steady-state current in the inductor is 25 A. a) What is the frequency of the inductor current? b) If the phase angle of the voltage is zero, what is the phase angle of the current? c) What is the inductive reactance of the inductor? d) What is the inductance of the inductor in millihenrys? e) What is the impedance of the inductor? 9.25 a) 如圖P9.25 所示,試求使阻抗Z ab 為純電阻性之頻率 ( rad/s )。 b) 如(a) 之頻率時,Z ab 值為何? 9.27 Find the impedance Z ab in the circuit seen in Fig. P9.27. Express Z ab in both polar and rectangular form. 9.31 Find the steady-state expression for i o (t) in the circuit in Fig. P9.31 if s = 100 sin 50t mV. 9.37 Find Z ab for the circuit shown in Fig P9.37. 9.45 Use source transformations to find the Thévenin equivalent circuit with respect to the terminals a,b for the circuit shown in Fig. P9.45. 9.46 Use source transformations to find the Norton equivalent circuit with respect to the terminals a,b for the circuit shown in Fig. P9.46. 9.54 Use the node-voltage method to find the steadystate expression for o (t) in the circuit in Fig. P9.54 if g1 20 cos(2000t 36.87) V, g 2 50 sin(2000t 16.26) V. 9.55 Use the node-voltage method to find V o in the circuit in Fig. P9.55. 9.60 Use the mesh-current method to find the steadystate expression for o (t) in the circuit in Fig. P9.54.